JP7408907B2 - Enhanced uplink behavior in soft handover - Google Patents

Description

TECHNICAL FIELD This invention relates to wireless communications. More particularly, the present invention relates to enhanced uplink (EU) operation during soft handover.

Mobile phone wireless communication networks are divided into multiple areas of interest. Each area of interest within the network is served by a Node B. As wireless transmit/receive units (WTRUs) move, they may move from one area of interest to another within a network.

A WTRU is served by a designated Node B for a particular area of interest. Since the regions covered by each Node B overlap each other, at the boundaries of the regions, a WTRU can establish a connection with more than one Node B. When a WTRU moves from one coverage area to another coverage area within a network, the WTRU undergoes a handover. Soft handover is widely used to ensure uninterrupted communication while moving between multiple cells.

Soft handover occurs when a WTRU is simultaneously connected to two or more Node Bs at the same time. In soft handover, all Node Bs serving the WTRU process the received data, which is routed to a radio network controller (RNC) for macro diversity combining. For simplicity, the RNC may use an error detection technique such as a CRC (Cyclic Redundancy Check) and accept packets that pass the CRC.

Softer handover is a special example of soft handover. When a WTRU is in softer handover, the WTRU is connected to two or more cells belonging to the same Node B. In contrast to soft handover, in softer handover macro diversity can be performed within the Node B with or without maximum ratio combining.

Automatic repeat request (ARQ) is a technique by which a receiver requests retransmission of a packet by a sender when an error is detected. Hybrid ARQ (H-ARQ) is a technique in which transmitted data blocks are encoded at the receiver side for partial error correction, and only data blocks with uncorrected errors are retransmitted. In the prior art, namely High Speed Downlink Packet Access (HSDPA), the H-ARQ function is terminated and controlled by the Node B (a technique called Node B Controlled H-ARQ), thereby preventing incorrectly received packets. can be sent and retransmitted quickly. This feature was highly desirable and practical since H-ARQ in HSDPA is not required for soft handover. Although this feature is highly desirable for the EU, problems exist as it is geared toward the EU (and H-ARQ) operating during soft handovers.

One of the problems with Node B controlled H-ARQ in soft handover conditions is link instability. The associated uplink (UL) and downlink (DL) control signaling does not benefit from soft handover, is error-prone, and requires significant power offset values. In the DL direction, the WTRU may not be able to receive acknowledgment (ACK) or negative acknowledgment (NACK) signals from all participating Node Bs. In the UL, all participating Node Bs may not be able to receive related control signaling from the WTRU. This may cause corruption of the soft buffer.

A soft buffer is a buffer for implementing H-ARQ at a Node B. Data packets received by the Node B but not acknowledged are stored in a soft buffer for incremental synthesis. Thus, data packets that have been transmitted but have not been previously acknowledged are combined with retransmissions of the same data packets that are transmitted in response to NACK signaling. Chase synthesis is a special case of incremental synthesis. Soft buffer corruption causes misalignment of H-ARQ protocols between different Node Bs, resulting in loss of the benefits of soft handover. It is desirable to achieve efficient H-ARQ operation without the problems associated with prior art systems.

Node Bs often make more efficient decisions and manage UL radio resources better than the RNC on a short-term basis, even when the RNC retains overall control on the Node B. can do. In order for a Node B to allocate UL radio resources to a WTRU in EU operation, the Node B must identify several WTRU specific parameters. In current 3GPP standards, only the RNC can identify WTRU-specific parameters using Radio Resource Control (RRC) messages. Therefore, it is necessary to forward that information to the Node B for proper scheduling of radio resources in EU transmission.

The RNC maintains an active set of cells for each WTRU in soft handover conditions. The RNC makes decisions to add or remove cells from the WTRU's active set based on measurements provided by the WTRU and Node Bs and on management of the available radio resources in each cell. In current 3GPP standards, the RNC applies RRC Radio Bearer (RB) control procedures to coordinate active set cells with the WTRU and Node B Application Part/Radio Network Subsystem Application Part (NBAP/RNSAP) radio link procedures. is applied to coordinate the active set cells with each Node B.

During soft handover, some information must be communicated between network entities to support EU operations. This information includes, but is not limited to, information related to the active set, information regarding the Node B controlling transmission during soft handover, EU scheduling information during soft handover, and ACK/NACK status information during soft handover. is included. Current 3GPP standards do not define a specific protocol to transfer the necessary information essential for EU operation during soft handover. Therefore, we define a protocol to transfer WTRU-specific information and other EU-related information between the RNC, Node Bs, and WTRUs to enable Node Bs to schedule radio resources and accurately connect EU connectivity during soft handovers. Need to handover.

The present invention relates to EU operation during soft handover in a wireless communication system. A wireless communication system includes a WTRU, at least two Node Bs, and an RNC. In accordance with one embodiment of the invention, one Node B per WTRU is designated as the primary Node B, and any other Node Bs in the EU active set are designated as non-primary Node Bs. The primary Node B controls EU operations during soft handover, including EU scheduling and H-ARQ. Soft buffer corruption is avoided by only the primary Node B controlling H-ARQ during soft handover. Alternatively, the RNC controls EU operations, including H-ARQ, during soft handover. In this case, the RNC generates the final ACK/NACK decision based on the Node B error checking results.

FIG. 1 is a diagram of a first embodiment of the invention. FIG. 1 is a diagram of a first embodiment of the invention. FIG. 3 is a diagram of a second embodiment of the invention. FIG. 3 is a diagram of a second embodiment of the invention. FIG. 3 is a diagram of a third embodiment of the invention. FIG. 3 is a diagram of a third embodiment of the invention. FIG. 4 is a diagram of a fourth embodiment of the present invention. FIG. 4 is a diagram of a fourth embodiment of the present invention. FIG. 3 shows a simplified connection between a Node B and an RNC according to the invention; FIG. 2 is a system diagram for transferring ACK/NACK signals according to the present invention. FIG. 2 is a system diagram for transferring ACK/NACK signals according to the present invention. 3 is a system and process diagram for softer handover according to the present invention; FIG. 3 is a system and process diagram for softer handover according to the present invention; FIG. FIG. 4 is a diagram of transferring WTRU-specific information between network entities in accordance with the present invention. 3 is a diagram of transferring information between network entities during handover according to the present invention; FIG.

The present invention will now be described with reference to the accompanying drawings, in which like elements are represented by like numerals throughout.

When referred to below, the term "WTRU" includes, but is not limited to, user equipment, mobile stations, fixed or mobile subscriber units, pagers, or any other type of equipment capable of operating in a wireless environment. When referred to below, the term "Node B" includes, but is not limited to, a base station, site controller, access point, or any other type of interface device in a wireless environment.

1A and 1B are diagrams of a system 100 and process 150 of a first embodiment of the invention. The WTRU 102 establishes connectivity with at least two cells controlled by different Node Bs 104a, 104b for soft handover. Data packets transmitted from the WTRU 102 are received and processed separately by at least two Node Bs 104a, 104b during soft handover (step 152).

One of the group of Node Bs in the "active set" is designated as the primary Node B 104a, and the other Node Bs in the active set are designated as non-primary Node Bs 104b. RNC 106 or WTRU 102 makes this determination (step 152). If the RNC 106 makes a decision, the RNC 106 notifies all Node Bs 104a, 104b and the WTRU 102. If the WTRU 102 makes a decision, the WTRU 102 notifies either all Node Bs 104a, 104b or the RNC 106 which in turn notifies all Node Bs 104a, 104b.

In making the decision regarding the primary Node B 104a, the RNC 106 uses statistics, ie, the number of successful decodings by the Node B 104a, 104b for a particular WTRU's transmission, to identify the Node B 104a, 104b with the best UL performance. What is evaluated is the performance of the best cell controlled by the Node B, and not the performance of all cells associated with the Node B. The RNC 106 also selects the primary Node B 104a by evaluating both the UL performance described above and the DL performance obtained from WTRU 102 measurements. RNC 106 then informs Node Bs 104a, 104b and WTRU 102 which will become the primary Node B 104a through Iub signaling and RRC signaling, respectively. The WTRU 102 is also informed of the primary Node B 104a through fast layer 1 signaling from the Node B.

The primary node B 104a may employ incremental synthesis, and the non-primary node B 104b may or may not use incremental synthesis. If the non-primary Node B 104b does not use incremental synthesis, the non-primary Node B 104b uses simple ARQ and constantly refreshes its buffers and does not perform any synthesis. This scheme solves the problem of soft buffer corruption in soft handover situations. If both the primary Node B 104a and the non-primary Node B 104b perform incremental combining, the destruction of the soft buffer is in the physical control signaling sent by the WTRU 102 that informs the Node B 104a, 104b which data packet is being transmitted. It may be resolved using a new data indicator or sequence number. Thereby, the Node Bs 104a, 104b can manage the soft buffers without destroying them.

All Node Bs 104a, 104b in the active set receive data packets from the WTRU 102 (step 154). Each Node B 104a, 104b performs error checking on the data packet and generates an indication of success or failure in decoding the data packet (step 156). Determining whether a data packet has been successfully received is performed through an error checking procedure, such as performing a cyclic redundancy check (CRC). The indication of success or failure in decoding a data packet by a Node B can be configured in various different forms, but will be referred to below as a CRC result or an ACK/NACK in all embodiments of the invention. However, since any type of error checking may be performed in accordance with the techniques of the present invention, the term "CRC" or "ACK/NACK" is used for illustrative purposes only and not as a limitation of the present invention. You have to understand that there is no.

If the Node B 104a, 104b correctly decodes the data packet, as determined by the error check, the Node B 104a, 104b transmits the data packet to the RNC 106. Once the primary Node B 104a derives the ACK from the data packet, it sends an ACK signal to the WTRU 102 and RNC 106 and refreshes the soft buffers (step 158), without waiting for the CRC result from the non-primary Node B 104b. If the primary Node B 104a derives a NACK from the data packet, it sends the NACK to the RNC and waits for a final decision from the RNC or a CRC result from the non-primary Node B forwarded through the RNC 106 (step 158 ). The primary Node B 104a may set a timer as described below. The primary Node B 104a sends an ACK/NACK signal to the WTRU 102 according to the final decision made by the RNC 106 or the CRC results forwarded from the non-primary Node B 104b.

The non-primary Node B 104b sends the data packet to the RNC 106 only if it derives an ACK from the data packet (step 158). RNC 106 makes an ACK/NACK determination (step 160). If the RNC 106 receives at least one ACK from the Node B 104a, 104b, the RNC 106 makes an ACK determination, and if the RNC 106 does not receive an ACK from the Node B 104a, 104b within a predetermined period of time, the RNC 106 makes a NACK determination. . The RNC 106 sends the ACK/NACK decision to the primary Node B 104a. The RNC 106 may not send an ACK determination to the primary Node B 104a if the primary Node B 104a derives an ACK. The RNC 106 optionally sends ACK/NACK decisions to the non-primary Node B 104b for soft buffer management depending on the manner of incremental combining at the non-primary Node B 104b.

RNC 106 optionally uses packets delivered from non-primary Node Bs 104b. If the RNC 106 uses packets delivered from non-primary Node Bs 104b, the media access control (MAC) functionality of the RNC 106 uses an unordered delivery mechanism on all packets received from all involved Node Bs 104a, 104b. Execute. When the Radio Link Control (RLC) layer identifies an out-of-order transmission, it assumes data is lost and requests retransmission. If an RNC 106 does not use packets delivered from non-primary Node Bs 104b, it processes only packets it receives from primary Node Bs 104a. RNC 106 extracts the data packets and places them into a MAC level reordering buffer. After the RNC MAC performs the reordering process, it sends the data to the RLC layer. Identify missing packets and notify the WTRU 102 through RLC messaging.

Optionally, a simplified connection may be implemented in the transmission of error checking results between the Node B and the RNC. A fast and simplified connection will be described with reference to FIG. The simplified connection is dedicated to fast signaling between the RNC 506 and the Node Bs 504a, 504b, eliminating long delays between the RNC 506 and the Node Bs 504a, 504b. A fast and simplified connection 510a, 510b is established between the Node B 504a, 504b and the RNC 506. CRC results from Node B 504a, 504b to RNC 506 and ACK/NACK results from RNC 506 to Node B 504a, 504b are sent over simplified connections 510a, 510b. No direct physical connection is required between Node Bs 504a, 504b. Rather, a logical channel between Node Bs 504a, 504b is required. RNC 506 coordinates the installation of logical channels.

The fast and simplified connection 510a, 510b is implemented using two alternatives. According to the first alternative, two logical channels are established between the RNC 506 and the two Node Bs 504a, 504b, respectively. The RNC 506 receives H-ARQ signaling 510b from one Node B 504b and processes it before forwarding 510a to another Node B 504a. The RNC 506 recognizes the state of H-ARQ processing of each Node B 504a, 504b by processing the signaling. As mentioned above, the CRC results are processed by the RNC 506, which makes the final ACK/NACK decision and sends the ACK/NACK decision to the Node Bs 504a, 504b.

Upon receiving the first ACK within the RNC 506 from any Node B 504a, 504b, the RNC 506 sends an ACK decision to all Node Bs 504a, 504b. If all Node Bs 504a, 504b derive NACKs, it takes some time to wait for all Node Bs 504a, 504b to provide CRC results. Therefore, the RNC 506 may optionally set a timer to wait for all Node Bs to respond, and when the timer expires, the RNC 506 may send a NACK to all Node Bs 504a, 504b.

According to the second alternative, a single logical channel is established between the two Node Bs 504a, 504b via the RNC 506. The RNC 506 receives the CRC result from one Node B 504b and only forwards it to another Node B 504a without processing it. This process is fast because the signaling is only routed between Node Bs 504a, 504b without being processed at the RNC 506. Therefore, this avoids processing delays and protocol delays in the RNC 506. Each Node B 504a, 504b derives the ACK/NACK decision based on the CRC results it collects from all participating Node Bs 504a, 504b in the active set. If there is at least one ACK from any Node B, a final ACK decision is made at each Node B 504a, 504b. Otherwise, the Node B 504a, 504b makes the final NACK decision. As described above, each Node B 504a, 504b generates an ACK decision upon receipt of the first ACK from any of the Node Bs 504a, 504b. A Node B 504a, 504b sets a timer to wait for an ACK from another Node B 504a, 504b, and if the Node B 504a, 504b does not receive any ACK by the expiration of the timer, the Node B 504a, 504b makes a NACK decision. generate.

A simplified connection between the Node Bs 504a, 504b and the RNC 506 may be implemented in any embodiment of the invention described herein.

The signaling of the ACK/NACK decision between the RNC and the Node B will be described with reference to FIGS. 6 and 7. FIG. 6 shows a system 600 in which a non-primary Node B 604b has the same Controlling RNC (CRNC) 606 as the primary Node B 604a. In this case, the CRNC 606 sends an asynchronous ACK to the WTRU 602 via the primary Node B 604a.

FIG. 7 shows a system 700 in which a non-primary Node B 704b has a CRNC 706b that is different from the CRNC 706a of the primary Node B 704a. In this case, the serving RNC (SRNC) 707 sends an asynchronous ACK to the WTRU 702 via the primary Node B 704a.

2A and 2B are diagrams of a system 200 and process 250 of a second embodiment of the invention. In this second embodiment, incremental combining is performed at each Node B 204a, 204b such that the Node B 204a, 204b combines transmissions of previous data packets with the same data with or without increased redundancy from the WTRU 202. Combine with packet retransmission.

The WTRU 202 establishes connectivity with at least two cells controlled by different Node Bs 204a, 204b for soft handover, and data packets transmitted from the WTRU 202 are separately received and processed by the Node Bs 204a, 204b (step 252). Each Node B 204a, 204b performs error checking on the data packets and generates a CRC result (step 254). Each Node B 204a, 204b sends its CRC result to the RNC 206. At the same time, each Node B 2041, 204b also sends its CRC result to the WTRU 202 (step 256). The WTRU 202 makes a determination as to whether there is at least one ACK received from the Node B 204a, 204b (step 258). The WTRU 202 may receive both ACK and NACK signals from the Node Bs 204a, 204b. If the WTRU 202 does not receive any ACKs, it schedules retransmission of the data packet (step 264). Node Bs 204a, 204b perform incremental combining of retransmissions and previous transmissions. If the WTRU 202 receives at least one ACK from either Node B 204a, 204b, the WTRU 202 transmits the next data packet (step 262).

The RNC 206 also makes ACK/NACK decisions based on the ACK/NACK signals it collects from the Node Bs 204a, 204b (step 260). The RNC 206 generates and transmits an ACK determination if the RNC 206 receives at least one ACK from the Node Bs 204a, 204b (step 268). Otherwise, the RNC 206 generates and sends a NACK decision to the Node Bs 204a, 204b (step 270). The ACK/NACK decision is sent to the Node B 204a, 204b. Each Node B 204a, 204b refreshes its soft buffer once it receives the ACK decision from the RNC 206 (step 272). This method is used to eliminate soft buffer corruption.

3A and 3B are diagrams of a system 300 and process 350 of a third embodiment of the invention. The WTRU 302 establishes at least two connections with cells controlled by different Node Bs 304a, 304b for soft handover. Data packets transmitted by the WTRU 302 are received and processed separately by at least two Node Bs 304a, 304b during soft handover (step 352). Each Node B 304a, 304b performs error checking on the data packets and generates an ACK/NACK result based on the error checking on the data packets it receives (step 354). A Node B coordinator 308 is provided to coordinate between the Node Bs 304a, 304b and between the Node Bs 304a, 304b and the RNC 306. Each Node B 304a, 304b sends an ACK/NACK result to the Node B coordinator 308 (step 356). In this embodiment, the final decision whether to send an ACK or NACK to the WTRU 302 is made by the Node B coordinator 308. It is determined whether either of the related nodes B 304a, 304b has generated an ACK as a result of the error check (step 358). In that case, the Node B coordinator 308 may flush out the corresponding soft buffers for all participating Node Bs 304a, 304b, respectively, to prepare for new transmissions, regardless of the results of the error checks derived at each Node B 304a, 304b. (step 360). In response, each Node B 304a, 304b sends an ACK to the WTRU 302 to refresh its soft buffer (step 362).

If the error checks from all Node Bs 304a, 304b fail (i.e., all Node Bs 304a, 304b generate a NACK) or the response timer Node B Coordinator times out, the Node B Coordinator 308 notifies all Node Bs 304a, 304b that it has failed to successfully decode the transmitted data packet and that they must prepare for retransmission of the data packet (step 364). In response, the Node Bs 304a, 304b send a NACK to the WTRU 302 (step 366).
4A and 4B are diagrams of a system 400 and process 450 of a fourth embodiment of the invention. For soft handover, the WTRU 402 establishes separate connections with at least two cells controlled by different Node Bs 404a, 404b in the active set. Data packets transmitted by the WTRU 402 are received and processed separately by the Node Bs 404a, 404b during soft handover (step 452). Each Node B 404a, 404b performs error checking on the received data packet and generates an indication of success or failure of decoding the data packet (step 454).

Each Node B 404a, 404b sends the CRC result to the RNC 406 (step 456). If the Node B 404a, 404b successfully decodes the data packet, the Node B 404a, 404b sends an ACK along with the data packet to the RNC 406. If the Node B 404a, 404b fails to decode the data packet, the Node B 404a, 404b sends a NACK to the RNC 406. ACKs and NACKs are sent with each data block within the Iub/Iur frame protocol between the Node Bs 404a, 404b and the RNC 406. The RNC 406 makes a final ACK/NACK decision for the transmission of the data packet from the results of the error checks performed by the Node Bs 404a, 404b (step 458). The RNC 406 makes an ACK determination if it receives at least one ACK from the Node Bs 404a, 404b. Otherwise, RNC 406 makes a NACK decision. The ACK or NACK decision by the RNC 406 is then sent back to the Node Bs 404a, 404b in steps 460 and 464, respectively. Each Node B 404a, 404b clears its buffer upon receiving the ACK decision from the RNC 406. All Node Bs 404a, 404b transmit the same ACK or NACK signal that the RNC 406 generates to the WTRU 402, regardless of the CRC results that each Node B 404a, 404b independently derives from the data packet ( steps 462 and 466). In this case, the WTRU 402 may apply maximum ratio combining (MRC) to the ACK/NACK feedback signals received from the Node Bs 404a, 404b.

The soft buffer within each Node B 404a, 404b is managed according to the ACK/NACK decisions made by the RNC 406 regardless of the associated error check results derived by the Node B 404a, 404b. As a result, the fourth embodiment of the present invention allows the RNC 406 to align the soft buffer state within each Node B 404a, 404b. Additionally, the WTRU 402 may benefit from soft handover for ACK/NACK signaling since all Node Bs 404a, 404b transmit the same ACK/NACK signaling. As such, since the ACK/NACK signals returned to the WTRU 402 from all associated Node Bs 404a, 404b are the same, the WTRU 402 may perform macro-diversity combining on the ACK/NACK signaling. I can do it.

A fifth embodiment of the present invention will be described with reference to FIG. 2A. The fifth embodiment is similar to the second embodiment except that the Node Bs 204a, 204b do not perform incremental synthesis during soft handover. The WTRU 202 establishes connectivity with at least two cells controlled by different Node Bs 204a, 204b for soft handover. Data packets transmitted by the WTRU 202 are received and processed separately by at least two Node Bs 204a, 204b during soft handover. Each Node B 204a, 204b performs error checking on the data packets and sends an ACK/NACK signal to the WTRU 202. The Node B 204a, 204b sends an ACK to the RNC 206 along with the transmission identifier. While sending a series of data packets, the WTRU 202 looks at the MAC level and looks for an ACK from any Node B 204a, 204b when in soft handover, or only from the current Node B when not in soft handover. This method causes retransmissions either when a timeout threshold for ACK is exceeded or when all cells report out of order. Alternatively, this embodiment may be implemented in conjunction with other embodiments, including the first embodiment shown in FIG. 1A.

8A and 8B are diagrams of a system 800 and process 850 for softer handover in accordance with the present invention. During softer handover, the WTRU 802 establishes connections with two or more cells 808 controlled by the same Node B 804 (step 852). EU transmissions from the WTRU 802 are processed independently by each of the cells 808 (step 854), and each of the cell 808 transmissions received from the WTRU 802 is processed by the Node B 804 that controls those cells (step 856). . There are two alternatives for incremental combining of transmissions sent by the WTRU 802.

According to a first alternative, the Node B 804 receives data packets from all participating cells 808 and combines them using a technique such as maximum ratio combining before performing error checking on the data packets. The resulting composite data packet is error checked at Node B 804.

According to a second alternative, each cell 808 independently processes data packets to determine error checks in data packets received from the WTRU 802. Node B 804 accepts data packets that pass error checks in any of the cells 808 in the active set.

On the downlink, the Node B 804 sends a message including an ACK/NACK to the WTRU 802 via all participating cells 808 (step 858). The WTRU 802 needs to monitor all channels, preferably shared channels, from the participating cell 808 to detect downlink messages. The number of shared channels that the WTRU 802 must monitor from each of the cells 808 is limited, such as up to four channels.

One of the cells 808 may be designated as a primary cell 808a and the other cells may be designated as non-primary cells 808b. Primary cell 808a sends the message on any of the downlink shared channels assigned to WTRU 802. This message carries a shared channel indicator for non-primary cell 808b. Non-primary cell 808b sends messages on the channel indicated by the shared channel indicator. To implement this scheme, there is a time lag between the transmission of the shared channel indicator from the primary cell 808a and the transmission of the message from the non-primary cell 808b. The WTRU 802 first monitors all shared channels from the primary cell 808a. When the WTRU 802 detects that one of the shared channels is carrying a message for the WTRU 802, the WTRU 802 reads the shared channel indicator along with the downlink message from the primary cell 808a. The WTRU 802 then receives a message from the non-primary cell 808b indicated by the shared channel indicator. Using this scheme, the number of channels that the WTRU 802 must monitor can be reduced. The WTRU 802 then combines the messages it receives from all participating cells 808 using a technique such as maximum ratio combining.

Alternatively, for DL, only the primary cell 808a may send messages to the WTRU 802. Node B 804 transmits downlink messages via primary cell 808a and all non-primary cells 808b disconnect downlink signaling to WTRU 802. Using this scheme, the WTRU 802's reception processing is simplified and downlink interference is reduced.

FIG. 9 is a diagram of a system 900 that transfers WTRU-specific information to support EU operations 912 in accordance with the present invention. Initially, the RNC 906 obtains WTRU-specific information from the WTRU 902 using RRC messaging 908 during the initial connection. The WTRU specific information is then forwarded from the RNC 906 to the Node B 904 and used for scheduling EU transmissions for the WTRU 902. Information transfer from the RNC 906 to the Node B 904 is via the Iub interface 910 or, if the SRNC is not the same as the CRNC, the Iur interface. A new signaling mechanism is utilized to transfer information from RNC 906 to Node B 904. Alternatively, existing mechanisms on the Iur and Iub interfaces may be modified for the RNC 906 to forward relevant WTRU-specific information to the Node B 904.

FIG. 10 is a diagram of a system 1000 for transferring information between network entities during soft handover in accordance with the present invention. During EU operation, if the WTRU 1002 needs to change serving cell or serving Node B, a soft or softer handover is initiated. In the following, for the sake of simplicity, the invention will only be described with respect to soft handover. During soft handover, some information must be communicated between network entities to support EU operations. This information includes, but is not limited to, information about the active set, information about the primary Node B if the system so specifies, EU scheduling/rate information, and ACK/NACK status information.

RNC 1006 maintains an active set of cells for handover. The RNC 1006 selects and removes cells in the active set based on measurements reported from the Node Bs 1004a, 1004b and the WTRU 1002 and available radio resources. Once the RNC 1006 selects a cell for the active set, the RNC 1006 sends a message to the Node Bs 1004a, 1004b and the WTRU 1002 informing them of the selected cell for the active set to support soft handover to the EU. Each time a cell is added or removed from the active set, RNC 1006 sends a message to update the active set. This message is sent using existing RRC and NBAP/RNSAP active set management procedures or new procedures.

Either the RNC 1006 or the Node Bs 1004a, 1004b and the WTRU 1002 may designate one Node B as the primary Node B 1004a and other Node Bs in the active set as non-primary Node Bs 1004b during soft handover. A primary Node B 1004a is selected based on the UL performance measured and reported by each Node B 1004a, 1004b and/or the DL performance measured and reported by the WTRU 1002.

During soft handover, only the primary Node B 1004a performs scheduling and allocation of radio resources for the WTRU 1002. The primary Node B 1004a notifies the RNC 1006 of scheduled EU transmissions via IubNBAP signaling or within the EU frame protocol. The RNC 1006 then informs the non-primary Node B 1004b of the allocation of radio resources for the EU and the routing of the received data. This is signaled on NBAP or also in the EU frame protocol. Alternatively, the non-primary Node B 1004b is informed of the set of EU physical channels for the period that each cell is in the active set by the IubNBAP procedure. Each of the non-primary Node Bs 1004b in the active set continuously receives these channels independently of the radio resource allocation scheduled by the primary Node B 1004a.

Although features and elements of the invention have been described in preferred embodiments in particular combinations, each feature or element may be used alone or without other features and elements of the preferred embodiments. It can also be used in various combinations with or without other features and elements.

100,200,300,400,500 System 102,202,302,402,502 WTRU
104,204,304,404,504 Node B
106,206,306,406,506 RNC
308 Node B Coordinator

Claims (13)

transmitting a data packet via a primary cell and a non-primary cell, the data packet being transmitted via the primary cell and the non-primary cell on an enhanced uplink (EU);
In a situation where the transmitted data packet is not correctly decoded by the primary cell and also not correctly decoded by the non-primary cell,
receiving a negative acknowledgment (NACK) signal from the primary cell and not receiving a NACK signal from the non-primary cell;
retransmitting the data packet in response to receiving a NACK signal from the primary cell even if a NACK signal from the non-primary cell is not received. 2. The method of claim 1 , wherein at least one of an acknowledgment (ACK) signal and the NACK signal is received via the primary cell on one or more downlink channels. 2. The method of claim 2, further comprising receiving a shared channel indicator from the primary cell, the shared channel indicator indicating via which of the one or more downlink channels a downlink message may be received. The method described in. The method of claim 1, further comprising receiving a downlink message via the primary cell upon handover. a wireless transceiver,
comprising a processor;
By the wireless transceiver and the processor,
transmitting a data packet via a primary cell and a non-primary cell, the data packet being transmitted via the primary cell and the non-primary cell on an enhanced uplink (EU);
In a situation where the transmitted data packet is not correctly decoded by the primary cell and also not correctly decoded by the non-primary cell,
receiving a negative acknowledgment (NACK) signal from the primary cell and not receiving a NACK signal from the non-primary cell;
The apparatus is configured to retransmit the data packet in response to receiving a NACK signal from the primary cell even if a NACK signal is not received from the non-primary cell. 6. The apparatus of claim 5 , wherein at least one of an acknowledgment (ACK) signal and the NACK signal is received via the primary cell on one or more downlink channels. A shared channel indicator is received from the primary cell by the wireless transceiver and the processor, the shared channel indicator indicating on which downlink channel the receiver is allowed to receive downlink messages, and so on. 7. The apparatus of claim 6 , configured. 6. The apparatus of claim 5 , configured by the wireless transceiver and the processor to receive downlink messages via the primary cell upon handover. 6. The device of claim 5 , wherein the device is a wireless transceiver unit. A method of operating a mobile phone network, the mobile phone network including a primary cell and a non-primary cell, the method comprising:
receiving data packets from a wireless transmit/receive unit (WTRU) via a primary cell and a non-primary cell, the data packets being transmitted to the primary cell and the non-primary cell on an enhanced uplink (EU); The steps are sent through the
In a situation where the transmitted data packet is not correctly decoded by the primary cell and also not correctly decoded by the non-primary cell, a negative acknowledgment (NACK) signal is transmitted from the primary cell and the data packet is not decoded correctly by the non-primary cell. does not transmit a NACK signal. 11. The method of operating a mobile telephone network according to claim 10 , further comprising receiving retransmissions of the data packets in response to transmission of a NACK signal from the primary cell. 11. The method of operating a mobile telephone network according to claim 10 , wherein at least one of an acknowledgment (ACK) signal and the NACK signal is transmitted by the primary cell on one or more downlink channels. 13. The WTRU of claim 12 , further comprising transmitting a shared channel indicator via the primary cell, the shared channel indicator indicating via which downlink channel the WTRU is allowed to receive messages. How to make a mobile phone network work.

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